PowerPoint PresentationWind-driven surface currents
Intentional
Inadvertent
Indirect methods
Pressure gradients
Figure 7B
Ocean currents
Surface currents
Affect surface water within and above the pycnocline (10% of ocean
water…I think it is more like 25% of ocean water)
Driven by major wind belts of the world
Deep currents
Affect deep water below pycnocline (90% of ocean water…I think it
is more like 75%)
Driven by density differences
NO CLEAR CUT DELINEATION
Deep water masses:
Are created when high density surface water sinks
Factors affecting density of surface water:
Temperature (most important factor)
Salinity
Deep currents which transport deep waters are also known as
thermohaline circulation
Characteristics of deep waters are determined AT THE SURFACE
Deep ocean characteristics
Cold
Still
Dark
Identification of deep water masses
Deep water masses are identified by measuring temperature (T) and
salinity (S), from which density can be determined
T-S diagram
Figure 7-25
4 Primary things that need to be understood
- Ekman transport (and spiral)
- The idea of Convergence
Ekman spiral: Wind Driven (τ)
Ekman spiral describes the speed and direction of flow of surface
waters at various depths
Factors:
Coriolis effect pushes water to right(left)
Due to shear, water velocity spins to the right(left) with
depth.
Figure 7-6
Ekman transport
Ekman transport is the overall water movement due to Ekman
spiral
Ideal transport is 90º from the wind
Transport direction depends on the hemisphere
Ekman transport is proportional to the speed of the wind. Higher
wind, higher transport!
Figure 7-6
4 Primary things that need to be understood
- Ekman transport (and spiral)
- The idea of Convergence
Convergence/Divergence
This idea is nothing more then the piling up or moving of water
away from a region.
Conservation of VOLUME: (du/dx+dv/dy+dw/dz=0)
Rearranging... du/dx + dv/dy = -dw/dz
If water comes into the box (du/dx + dv/dy)>0 there is a
velocity out of the box: dw/dz < 0 DOWNWARD
So lets go back to Ekman…and see where water is piled up and where
it is emptied.
Convergence (Divergence) across a mid ocean gyre
Understanding the formation of currents
4 Primary things that need to be understood
- Ekman transport (and spiral)
- The idea of Convergence
- Geostrophic Balance
Vorticity (I think the 3rd time we’ve talked about it)
Vorticity is analagous to angular momentum.
Vorticity is a conserved quantity (Conservation of Vorticity)
When we talked about Coriolis we introduced the idea of Planetary
Vorticity (f). Every object on earth has a vorticity given to it by
the rotation of the earth (except an object on the equator). This
vorticity is dependent on latitude.
Each object on earth can have Relative Vorticity as well. An ice
skater who is spinning has Relative Vorticity. A skater who becomes
more skinny spins faster (greater relative vorticity). But remember
that water is incompressible. So if a water column becomes ‘skinny’
it MUST become taller at the same time!
TOTAL VORTICITY is CONSERVED BY FLUIDS.
Planetary (f) + Relative (ξ) = Constant H
H is the (tallness, or depth of water column)
North Pole (High planetary Vorticity f)
Equator (Zero planetary Vorticity f)
A parcel of water moves off the equator its vorticity on the
equator (f+ ξ )=0.
Off the equator (to the north) Planetary Vorticity (f) > 0.
Since (f + ξ )=0, ξ must be < 0. The water begins to spin.
Right Hand Rule: Curl your fingers on your right hand (northern
hemisphere) in the direction of spin. If you thumb points upward
the vorticity is positive. If you thumb points downward, vorticity
is negative.
An example of conservation of vorticity when H stays constant
Ocean Surface
Ocean bottom
A parcel of water moves east (constant latitude) in N.Hemis.
As the parcel hits the bump, H decreases. We know that (f +
ξ)/H=Constant. So if H decreases, (f + ξ) must decrease. If f
decreases, the parcel moves equatorward. If ξ decreases the parcel
spins clockwise.
Right Hand Rule: Curl your fingers on your right hand (northern
hemisphere) in the direction of spin. If you thumb points upward
the vorticity is positive. If you thumb points downward, vorticity
is negative.
An example of conservation of vorticity when H doesn’t stay
constant
H
Ocean Surface
Ocean bottom
A parcel of water moves east (constant latitude) in N.Hemis.
As the parcel hits the bump, H decreases. We know that (f + ξ
)/H=Constant. So if H decreases, (f + ξ ) must decrease. If f
decreases, the parcel moves equatorward. If ξ decreases the parcel
spins clockwise. Or a combination.
Right Hand Rule: Curl your fingers on your right hand (northern
hemisphere) in the direction of spin. If you thumb points upward
the vorticity is positive. If you thumb points downward, vorticity
is negative.
An example of conservation of vorticity when H doesn’t stay
constant
H
A parcel of water moves east (constant latitude) in N.Hemis.
As the parcel hits the bump, H decreases. We know that (f + ξ
)/H=Constant. So if H decreases, (f + ξ ) must decrease. If f
decreases, the parcel moves equatorward. If ξ decreases the parcel
spins clockwise. Or a combination.
Right Hand Rule: Curl your fingers on your right hand (northern
hemisphere) in the direction of spin. If you thumb points upward
the vorticity is positive. If you thumb points downward, vorticity
is negative.
An example of conservation of vorticity when H doesn’t stay
constant
Bump in bottom
4 Primary things that need to be understood
- Ekman transport (and spiral)
- The idea of Convergence
- Geostrophic Balance
Geostrophic Balance
Most large currents are in Geostrophic balance. Which terms from
our momentum equation?
All currents are pushed to the right(left).
This piles water up on the right(left).
This creates a pressure force back towards the current.
Eventually a balance is reached. Pressure BALANCES Coriolis!
current
Sealevel
Geostrophic flow causes a hill to form in subtropical gyres
Example in the book of the balance of coriolis and pressure force
(gravity).
Current is Perpendicular to slope.
Current is along constant height
Figure 7-7
Understanding the formation of currents
We’ve been introduced to the 4 Primary things that need to be
understood. Let’s put them all together to understand what drives
our ocean currents!
- Ekman transport (and spiral)
- The idea of Convergence
Ekman transport creates convergence and divergence of upper
waters.
Convergence
Convergence
Divergence
Divergence
Divergence
Upwelling and Downwelling across a mid ocean gyre due to Ekman
Transport
Convergence causes downwelling! Divergence causes upwelling!
Ocean Surface
Mixed Layer
Ocean bottom
A parcel of water moves into an area of downwelling. It becomes
shorter (and fatter).
f/H must be conserved!
We know that (f + ξ)/H= Constant. So if H decreases, (f + ξ ) must
decrease. I gave examples before that either f or ξ could change.
But in this process; it is f that decreases. f can only decrease by
the parcel moving equatorward.
With DOWNWELLING, the vertical velocity is downward. This pushes on
the column of water, making it shorter (and fatter). What happens
when a column of water gets short and fat (Vorticity must be
conserved).
H
H
Ekman transport creates convergence and divergence of upper
waters.
Convergence
Convergence
Divergence
Divergence
Divergence
Ekman transport creates convergence and divergence of upper
waters.
Equatorward flow
Equatorward flow
Poleward flow
Poleward flow
Complicated flow
45o N
15o N
15o S
45o S
Geostrophic Balance
Ekman transport has caused a ‘hill’ to form in the sea surface when
convergence occurs (subtropical gyre)
Vorticity balance explains equatorward flow (from gyre center to
the east)
Geostropic current is along constant height (WARM water to right in
N Hemis)
Current must return back to the north (conservation of mass)
Western Boundary Current is that return. Very strong very
intense
Figure 7-7
Current gyres
Subtropical gyres
North Pacific, South Pacific, North Atlantic, South Atlantic,
Indian
Generally 4 currents in each gyre
Centered at about 30º north or south latitude (I think more like
25o)
Subpolar gyres
Centered at about 60º north or south latitude
Rotate in the opposite direction of adjoining subtropical
gyres
Sea Surface Height and Mean Geostrophic Ocean Circulation
H-Subtropical Gyre
L-Subpolar Gyre
H-Subtropical Gyre
H-Subtropical Gyre
H-Subtropical Gyre
H-Subtropical Gyre
L-Subpolar Gyre
HK Guam HA SF
The western boundary currents of all subtropical gyres are:
Fast
Narrow
Deep
Western Boundary Currents and Vorticity Conservation…Must
conserve.
North Pole (High planetary Vorticity f)
Equator (Zero planetary Vorticity f)
A parcel of water moves off the equator its vorticity on the
equator (f+ ξ )=0.
Off the equator (to the north) Planetary Vorticity (f) > 0.
Since (f + ξ )=0, ξ must be < 0. The water begins to spin.
Right Hand Rule: Curl your fingers on your right hand (northern
hemisphere) in the direction of spin. If you thumb points upward
the vorticity is positive. If you thumb points downward, vorticity
is negative.
Back to our example of conservation of vorticity when H stays
constant
Remember this example?
As the western boundary current returns north, this should happen,
but it does not. Why?
North Pole (High planetary Vorticity f)
Equator (Zero planetary Vorticity f)
A parcel of water moves off the equator its vorticity on the
equator (f+ ξ )=0.
Off the equator (to the north) Planetary Vorticity (f) > 0.
Since (f + ξ )=0, ξ must be < 0. The water begins to spin.
Back to our example of conservation of vorticity when H stays
constant
As the water moves up the coast in the VERY Narrow WBC, it rubs
against the coast. It removes vorticity through friction.
The WBC MUST be narrow, it must get close to the coast.
Conservation of Vorticity is valid as an idea. But once an outside
force like friction is applied, conservation is not going to
happen.
Parcel wants to spin
Wind-driven surface currents
Hoists cold, nutrient-rich water to surface
Produces high productivities and abundant marine life
Downwelling = movement of surface water down
Moves warm, nutrient-depleted surface water down
Not associated with high productivities or abundant marine
life
Coastal upwelling and downwelling
Ekman transport moves surface water away from shore, producing
upwelling
Ekman transport moves surface water towards shore, producing
downwelling
Figure 7-11
Figure 7-9
Equatorial upwelling
Other examples of upwelling (Which one looks like San Diego?)
Antarctic surface circulation
The Gulf Stream is a warm, western intensified current
Meanders as it moves into the North Atlantic
Creates warm and cold core rings
Rings move west. Argue as given in book for westward
intensification.
Figure 7-16
Currents and climate
Warm current warms air high water vapor humid coastal climate
Cool current cools air low water vapor dry coastal climate
Figure 7-8a
El Niño-Southern Oscillation (ENSO)
El Niño = warm surface current in equatorial eastern Pacific that
occurs periodically around Christmastime
Southern Oscillation = change in atmospheric pressure over Pacific
Ocean accompanying El Niño
ENSO describes a combined oceanic-atmospheric disturbance
Average conditions in the Pacific Ocean
Figure 7-18a
Figure 7-18b
La Niña conditions (ENSO cool phase; opposite of El Niño)
Figure 7-18c
The 1997-98 El Niño
Sea surface temperature anomaly map shows warming during severe
1997-98 El Niño
Internet site for El Niño visualizations
Current state of the tropical Pacific
Figure 7-19a
Typical recurrence interval for El Niños = 3-12 years
Pacific has alternated between El Niño and La Niña events since
1950
Figure 7-20
Figure 7-21
El Nino
La Nina
Measuring currents through satellite
Red: High sea level…High sea level is warmer water (water expands
when warm)…In N Hemisphere warm water is on the right. ONLY
measures anomaly, Must add GEOID.
Equatorial Currents are complicated…but they are still driven
EXACTLY THE SAME WAY as the gyres. The currents are complicated
because the winds are complicated and the equator is present (Why
would the equator be important?) f is nearly zero near the equator
so swashing and stretching of water columns isn’t the driving
force. The process is just ekman convergence/divergence and
pressure forces.
Topex/Poseidon dynamic topography after GEOID has been added
Ocean surface currents
Sverdrup: measure of flow rate (length3/time) 1 Sv = 106 m3/s
Pacific Ocean surface currents